Aviation Powerplants Essay Research Paper Aviation PowerplantsAviation

Aviation Powerplants Essay, Research Paper Aviation Powerplants Aviation has reshaped modern life and has provided for extreme convenience for traveling businessmen, vacationers, and thrillseekers alike. It also plays a key role in

Aviation Powerplants Essay, Research Paper

Aviation Powerplants

Aviation has reshaped modern life and has provided for extreme convenience for

traveling businessmen, vacationers, and thrillseekers alike. It also plays a key role in

military operations of all kinds. Although aircraft design progression plays a predominant

role in advancing speed, agility, utility, and entertainment; none of these would be

possible without powerplant development, refinement and modification.

Aviation powerplants originated with the Wright flyer and its small 2 cylinder

inline engines of a mere 45 horsepower. This style engine dominated aviation well into

the First World War. They were generally placed in pushing positions (rear-facing) and

produced a relatively low number of revolutions per minute (2500 RPM redline). There

was little need for new engine development at this time because aircraft design

progressed slowly.

Rotary engines became popular around 1910 and powered many fighters and

bombers in The First World War. These engines are placed in a radial pattern around the

crankshaft. These produced respectable horsepower numbers in the category of up to

185+. They were used in such famous aircraft as the Sopwith Camel and Moth. A

variation of the rotary engine was used in the most famous aircraft of the war: The

Fokker Dr.1 Triplane flown by Baron Von Richtofen. A unique feature of these engines

is that they had no throttle, but ran at a constant speed. Also the cylinders were not fixed

in place as one might expect. They instead rotated around a fixed crankshaft. The

propeller was attached to the cylinders. The advantage of this configuration was lowered

production time and elimination of a costly and vulnerable cooling system. Speed control

was gained by cutting the fuel supply and thus shutting down the engine. The engine

would retain enough momentum to allow the pilot to simply turn back on the fuel system

and restart the engine to get power.

Rotary and small inline engines soon gave way to the large Radial engines of

World War 2. These were configured in a radial pattern similar to that of Rotary engines.

They, however do not have a fixed crankshaft but instead directly spin the propeller from

a moving crankshaft. Throttles are included here to slow down for combat while still

staying out of a stall. The Radial engines produced immense amounts of horsepower.

One example of this is the 18 cylinder dual layer Pratt & Whitney R-2800 (from the P-47

Thunderbolt, also the best aircraft of the war). Stock, the engine produces 2100+

horsepower. This engine, when coupled with a Turbo-Supercharger (for altitudes above

20,000 feet) it produces 2500+ horsepower. The radial engines also boast survivability

far beyond that of inline or V-configurations. One 18 cylinder Radial was found with 17

30mm cannon shells imbedded in the engine block. The radial engine is a great package:

survivability, durability, reliability, power, and acceleration.

Inline water-cooled engines were also available during World War 2. These are

similar to the ones in standard cars, except they are larger (12 -24 cylinders) and develop

more horsepower (up to 1600). The drawbacks to using inline engines include:

vulnerability due to the necessity of a radiator; and a head on 30 mm cannon shot can

take out numerous cylinders and physically stall the engine.

Horizontally opposed engines are still used today in small private aircraft

(Cessna, Bonanza, etc.). These, however, do not use the distributors or computers used to

control the spark as do the newer cars. They instead use magnetos and spark plugs

because these technologies have been proven and used for nearly 100 years. Also, no fuel

injection is used but instead carburetors are the standard. They are standard FAA

approved equipment and will not likely be replaced soon.

In late 1945, the first turbofan engine was used in an active combat aircraft. The

turbofan provides enormous amounts of thrust (35,000 lbs. without afterburners, upwards

of 60,000 maximum with afterburners). The turbofan works in six stages:

1)Air is sucked into the intake and compressed in stages by turbine blades that spin

3/1000ths of an inch from each other. 4-6 stage compression.

2)Compressed air is injected with high explosive jet fuel and moves into the combustion


3)Air fuel mix is incinerated and the resulting superheated gases move into a second set

of fan blades.

4)Here the hot gasses (1800-2500 degrees) drive turbine blades that create energy to

augment the first compression stage’s effectiveness.

5)The gasses then move into an optional augmentor (more commonly known as an

afterburner) where raw jet fuel is forced into a second combustion chamber and is burned

immediately due to high temperatures.

6)Gasses escape from an exhaust nozzle and provide thrust.

The turboprop and turbojet engines follow the same principles as the turbofan but

with a few variations. The turboprop is simply a turbofan with a geared-down prop

attached to the main shaft of the fan blades. The turbojet compresses about 10% of the

incoming air and the rest bypasses the combustion chamber(s) and is used to cool the

blades, compressors, and generators.

A new experiment in propulsion is the ramjet. The ramjet is in principle one of

the simplest possible flight propulsion units. It is essentially a duct open at front and rear.

At high speed in flight, air is rammed into the front of the duct, whose shape immediately

reduces the air’s speed, compressing and heating it. In a combustion chamber, fuel is

injected into the airstream, which is ignited. Extremely high temperatures can be reached

and very high fuel efficiencies achieved. The intensely hot exhaust gas then exits in a

propulsive stream through a discharge nozzle. Unlike gas-turbine jet engines, the ramjet

can be used only to propel vehicles already in flight. Applications have been confined

mainly to missiles, where a ramjet takes over after a rocket has propelled the missile to

supersonic speeds. The experimental SCRAMJET (supersonic combustion ramjet) will

propel vehicles at hypersonic speeds (above Mach 6) with gases moving through the

combustion chamber at supersonic speeds.